Reactions Catalyzed by Potassium Fluoride. III. The Knoevenagel

hart and Winston, New York, N. Y., 1962, p. 217. (8) L.Pauling, “The .... (la) Present address: Boyce Thompson Institute for Plant Research,. Yonker...
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OCTOBER,1962

R E A C T I O X S CAT.4LYZED BY P O T A S S I U M F L U O R I D E .

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Reactions Catalyzed by Potassium Fluoride. 111. The Knoevenagel Reaction LEONRAND,JOSEPH V. SWISHER, AND CONSTANCE J. CRONIX Department of Chemistry, University of Detroit, Detroit, Michigan Received March 16,1962 The ability of potassium fluoride to serve as a basic catalyst in the Knoevenagel reaction was determined using benzaldehyde and cyclohexanone with malononitrile, ethyl cyanoacetate, and ethyl malonate. Rubidium and cesium fluorides were shown to be somewhat better than potassium fluoride in the same reactions.

and methylene compounds were employed with 0.5 mole-equivalent of the potassium fluoride.6 The yields were determined by either the method of product isolation or by measuring the decrease in concentration of reactants by vapor phase chromatography. In some cases both methods were used. In the chromatographic determinations where the yield of product was based on the decrease in concentration of the carbonyl compound, either toluene or tetralin was used as an internal standard, the choice based on efficiency of separation of each component. The yields as determined by either method generally corresponded quite closely. Analysis of the results shows that potassium fluoride, in less than molar-equivalent amounts, is effective as a basic catalyst with active methylene compounds. With the more easily dissociated active methylene compounds, a nonpolar solvent can be employed, but generally, a solvent with a greater polarity gives a higher yield for the same time of reaction. Thus, as would be expected, the reactions carried out in ethanol and dimethylformamide consistently showed higher yields than those carried out in benzene. One of the factors probably involved is the solubility of the potassium fluoride in the different solvents. \ CH2 + HkO 'CHI+ H30+ It was interesting to observe that in many of / kz / those reactions which occurred readily, the conwith malononitrile (IC, = 6.5 X 10-l2; kl = 0.9 centration of the active methylene compound as min.-l), ethyl cyanoacetate (k, < k1 = shown by vapor phase chromatography was several 0.07 min.-l), and ethyl malonate (ka = 5 X per cent lower than the concentration of the carICl = 0.0015 min.-') would serve as an indication of bonyl compound, particularly during the initial the degree of basicity of the potassium fluoride, hours, the reactions P-hich went over 80% in twentyassuming that little or' no product results from four hours did not show any difference in concenthose acids whose anion formation is not promoted tration when determined at that time. This could by the pot'assium fluoride. Tables I and I1 be taken as evidence of the fairly rapid formation of summarize the results of the use of potassium the anion and its rather slow attack on the carfluoride in nonaqueous solvents of varying polarity. bonyl group or a slow subsequent step, 2.e. the I n each case, equimolar quantities of the carbonyl dehydration step. Further evidence is gained from the fact that benzaldehyde reacted much (1) L. Rand and M. J. Albinak, J . Org. Chem., 26, 1837 (1960). (2) L. R a n d , W. Wagner, P. 0. Warner, and L. R. Kovac, ibad., more readily than cyclohexanone with the same 27, 1034 (1962). methylene compound. We are currently working (3)(a) H. Baba, H. llidorikawa. a n d S. Aoyama, J . Sci. Res. Inst., 62, 99 (1958); (b) H. Igarashi, H. Midorikawa, a n d S. Aoyama, ibid., on a kinetic study of these reactions using the alkali 6.2, 105 (1958); ( c ) 4 . Sakurai, H. Midorikawa, a n d S. Aoyama, ibid., metal fluorides. 62, 112 (1958); (d) H. Yasuda. H. Midorikawa, a n d S. Aoyania. Several reactions have been reported recently as being catalyzed by potassium fluoride. These reactions include the Hofmann reaction in which N-chlorobenzamide is converted into phenyl isocyanate in benzene solution, adipic and 2,2,5,5tetramethyladipic acids are cyclized to the corresponding cyclopentanones12 and various Knoevenagel condensations are e f f e ~ t e d . ~Since each of these reactions is typically base-catalyzed, the potassium fluoride appears to be acting as a base, even in nonpolar media. I n an effort to determine qualitatively the effectiveness of potassium fluoride as the base, the Knoevenagel reaction of benzaldehyde and cyclohexanone with various active methylene-containing compounds was studied. I n an earlier paper12 it was suggested that the potassium fluoride was capable of abstracting a proton from an acidic substance and subsequently giving it up to a base stronger than itself. The mechanism4 of the Knoevenagel reaction requires the formation of the anion of the active methylenecontaining compound. On the basis of measurements made by Pearson and Dillon5 on the rate constants of ionization of pseudo acids in water (equation 1) it, was expected that the Knoevenagel reaction

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ibid., 63,19 (1959): (e) A. Sakurai. ibid.. 63,260 (1959). (4) S. Patai and J. Zabicky, J. Chem. Soc., 2030 (1960). (5) R. G. Pearson and R. L. Dillon, J . Am. Chem. Soc.. 76, 2139 (1953).

(6) It was found t h a t concentrations of 0.26 t o 1.0 mole-equivalent of potassium fluoride did not appreciably alter the yield of products in this series.

RAKD,SWISHER, AND CRONIN

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VOL. 27

TABLE I CONDENSATIOX REACTIONS BETWEEN BENZALDEHYDE AND ACTIVEMETHYLENES CATALYZED BY POTASSIUM FLUORIDE Solvent

Temp., “C.

Ethyl cyanoacetate

Abs. ethanol Benzene DMF Abs. ethanol Benzene DMF

Ethyl malonate

Abs. ethanol

25 25 25 25 60 25 60 60

Active methylene

Malononitrile

Time, hr.

.-Yield VPC

of product, 70Isolated

100 94 89 100

93 84 100 100 90.5 89 100 0 0 4

1 1 1

1 6 6 6 6 24